D. Adriano, Trace elements in the terrestrial environment, 1986.

B. Alloway, Heavy metals in soils, second edition, Blackie. Academic & Professional, p.604, 1995.

. Cotentin, annexe 1 : Distributions de probabilité des paramètres, p.673

B. Gulson, K. Mizon, A. Law, M. Korsch, J. David et al., Source and 674 pathways of lead in humans from the Broken Hill mining community; an alternative use of 675 exploration methods Economic geology, pp.889-908, 1989.

K. Hogan, A. Marcus, R. Smith, and P. White, Integrated exposure uptake biokinetic model 677 for lead in children: empirical comparisons with epidemiologic data, Environmental Health Perspectives, vol.678, issue.6, pp.1557-67, 1998.

. Verneuil-en-halatte, France 682 ISO 11885 Water quality ? Determination of 33 elements by inductively coupled 683 plasma atomic emission spectroscopy 684, 1996.

A. Kabatia-pendias and H. Pendias, Trace elements in soils and plants, 1992.

K. Kawamoto and K. Park, Calculation of environmental concentration and comparison of 687 output for existing chemicals using regional multimedia modelling, 2006.

G. Khoury and G. Diamond, Risks to children from exposure to lead in air during 690 remedial or removal activities at Superfund sites: a case study of the RSR lead smelter 691, 2003.

P. Landrigan, Lead levels, home dust, and proximity to lead smelters, Pediatrics, vol.694, issue.4, pp.97603-97607, 1996.

Y. Luo and X. Yang, A multimedia environmental model of chemical distribution: Fate, transport, and uncertainty analysis, Chemosphere, vol.66, issue.8, pp.1396-1407, 2007.
DOI : 10.1016/j.chemosphere.2006.09.026

J. Maccrady and S. Maggard, Uptake and photodegration of 2, pp.8-698, 1995.

E. Mckone, A multimedia total exposure model for hazardous-waste sites. Part I-IV. 700 UCRL-CR-111456, 1993.

E. Mckone and K. Enoch, A multimedia total exposure. Spreadsheet user's guide 702, 2002.

H. Mielke and P. Reagan, Soil is an important pathway of human lead exposure, Environmental Health Perspectives, vol.704, issue.1, pp.217-246, 1998.

P. Mushak, Uses and limits of empirical data in measuring and modeling human lead exposure, Environmental Health Perspectives, vol.106, issue.Suppl 6, pp.1467-84, 1998.
DOI : 10.1289/ehp.98106s61467

N. Oreskes, Evaluation (not validation) of quantitative models, Environmental Health 713 Perspectives 6, pp.1453-1460, 1998.

S. Paterson, D. Mackay, and A. Gladman, A fugacity model of chemical uptake by plants from soil and air, Chemosphere, vol.23, issue.4, pp.539-565, 1991.
DOI : 10.1016/0045-6535(91)90203-P

G. Fidèle, Gestion des sites et sols contaminés, 2002.

H. Roels, J. Buchet, R. Lauwerys, P. Bruaux, F. Claeys-thoreau et al., Exposure to lead by the oral and the pulmonary routes of children living in the 721 vicinity of a primary lead smelter. Envrionmental research, pp.81-94, 1980.

M. Riederer, Estimating partitioning and transport of organic chemicals in the foliage/atmosphere system: discussion of a fugacity-based model, Environmental Science & Technology, vol.24, issue.6, pp.829-837, 1990.
DOI : 10.1021/es00076a006

M. Ruby, R. Schoof, W. Brattin, M. Goldade, G. Post et al., Advances in evaluating the 726 oral bioavailability of inorganics in soil for use in human health risk assessment, Environmental Science & Technology, vol.33, issue.21, pp.727-3697, 1999.

. Osnabrück and . Osnabrück, Germany 734 SRC (Syracuse Research Corporation) Biokinetic model for lead, Windows 735 version 1, ISE, p.41, 2003.

E. Stanek and E. Calabrese, Daily Soil Ingestion Estimates for Children at a Superfund Site, Risk Analysis, vol.20, issue.5, p.737, 2000.
DOI : 10.1111/0272-4332.205057

E. Stanek, E. Calabrese, and M. Zorn, Soil Ingestion Distributions for Monte Carlo Risk Assessment in Children, Human and Ecological Risk Assessment: An International Journal, vol.7, issue.2, pp.357-368, 2001.
DOI : 10.1080/20018091094402

S. Statsoft, Edition 99 for Windows, Kernel version 5.5. Information available at 741 http

K. Thompson and D. Burmaster, Parametric Distributions for Soil Ingestion by Children, Risk Analysis, vol.64, issue.2, p.743, 1991.
DOI : 10.1007/BF00377681

S. Trapp and J. Mcfarlane, Plant contamination: modelling and simulation of organic 745 chemical processes, 1994.

A. Tremel-shaub and I. Feix, Contamination des sols. Transferts des sols vers les plantes, 747 EDP Sciences, ADEME, 2005.

. Radioactive-waste and . Management, USA 756 US DOe (US Department of Energy) Agricultural and environmental input parameters 757 for the biosphere model. ANL-MGR-MD-000006 Rev02, Office of Civilian Radioactive, vol.758, 2004.

R. Volatier, Enquête I individuelle et nationale sur les consommations alimentaires, p.775, 2000.

M. Wilhelm, J. Wittsiepe, P. Schrey, A. Hilbig, and M. Kersting, Consumption of homegrown products does not increase dietary intake of arsenic, cadmium, lead, and mercury by young children living in an industrialized area of Germany, Science of The Total Environment, vol.343, issue.1-3, pp.61-70, 2005.
DOI : 10.1016/j.scitotenv.2004.09.039

C. Xintaras, Analysis Paper : Impact of lead-contaminated soil on public health. 788 ATSDR, Atlanta, vol.789, 1992.

M. Zupan, V. Hudnik, F. Lobnik, and V. Kadunc, Accumulation of Pb, Cd and Zn from (Plantago lanceolata L.) Contaminated soils: International conference on the 792 biogeochemistry of trace elements, Proceedings, vol.1595, issue.85, pp.325-335, 1995.